If you are participating in the presentations this year, please provide a written
report and a copy of your final report presentation by 31 October.
If not, please provide a written report by 30 September.
Part 1 - Summary Details
Please use your TAB key to complete Parts 1 & 2.
CRDC Project Number: DAQ0002
Project Title: Tobacco streak virus (TSV) in cotton
Project Commencement Date: 01/07/2008 Project Completion Date: 30/06/2011
CRDC Program: Value Chain
Part 2 – Contact Details
Administrator: Ms Helen Kamel, Principal Coordinator (External Funding)
Organisation: Dept of Employment, Economic Development and Innovation
Postal Address: Queensland Department of Employment, Economic Development
and Innovation, PO Box 102, Toowoomba, Qld 4350
Ph: 07 4688 1286 Fax: 07 4688 1190 E-mail: [email protected]
Principal Researcher: Mr Murray Sharman, Senior Plant Pathologist (Virology)
Organisation: Dept of Employment, Economic Development and Innovation
Postal Address: DEEDI, Level 2C-West, Ecosciences Precinct, GPO Box 267,
Brisbane, 4001
Ph: 07 3255 4339 Fax: 07 3846 2387 E-mail: [email protected]
Supervisor: Dr John Thomas, Principal Research Fellow
Organisation: University of Qld, Queensland Alliance for Agriculture & Food
Innovation
Postal Address: Level 2C-West, Ecosciences Precinct, GPO Box 267,
Brisbane, 4001
Ph: 07 3255 4393 Fax: 07 3846 2387 E-mail: [email protected]
Signature of Research Provider Representative:
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Part 3 – Final Report Guide (due 31 October 2008)
(The points below are to be used as a guideline when completing your final report.)
Background
1. Outline the background to the project.
Tobacco streak virus (TSV) has a worldwide distribution. It is transmitted by thrips and has a
wide host range including species in more than 30 plant families. Although TSV has been
known from Australia from at least the 1970s, the virus has not previously been recorded as
causing disease in any crops in the grain and cotton growing regions of Australia.
In 2006, TSV was identified as the causal agent of the devastating sunflower necrosis disease
in central Queensland (CQ), and subsequently in 2007 as the cause of major losses in
mungbeans in the same area. It has been a major factor in the recent downturn in the
sunflower industry in CQ. The diseases caused by TSV appear to have been present for a
several years prior in these and other crops. Our studies have shown that parthenium is a
major weed host of TSV in CQ and we have demonstrated thrips transmission. Surveys in
2007/2008 (as part of the one year scoping study 03DAQ005) found TSV in cotton in CQ.
The symptoms were mostly confined to the feeding sites of the thrips and appeared as reddish
spots and rings, but occasionally the plants were systemically infected and showed a chlorotic
mosaic and leaf deformation.
TSV has also recently been recorded on cotton from India (Bhat et al 2002) and Pakistan
(Ahmed et al 2003), but where described, the symptoms differ in being usually a chlorotic
mosaic, and genome sequence comparisons indicate that the Australian strain of the virus is
distinct.
The 2007-2008 growing season (during the scoping study) was abnormally wet in CQ, and
we needed to know how the disease may develop in cotton in more normal seasons. The
factors inducing systemic infection of cotton and the potential yield affects were also crucial
questions that needed to be addressed.
Many aspects of the epidemiology of TSV in CQ were unknown prior to this project
(DAQ0002) and the related GRDC project (DAQ00130), including the role of many potential
weed hosts and possible thrips vector species. These knowledge gaps were jointly addressed
in the complementary GRDC project and the linking of these two projects has provided
synergies to maximise efficiencies in this research.
Objectives
2. List the project objectives and the extent to which these have been achieved.
Objective 1. Surveys to assess the incidence, distribution and impact of TSV
This objective has been achieved. Disease surveys were conducted at multiple
times during each growing season from 2008 to 2011 in central Queensland.
Cotton samples were also tested from southern Qld and northern NSW cotton
crops in most seasons.
Objective 2. Determine the thrips vector species associated with cotton
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This objective has been achieved. Thrips species were collected and identified
from multiple seasons and locations in cotton crops affected by TSV in central
Qld.
Objective 3. Examination of factors that lead to systemic infection of cotton
This objective was partly achieved. Multiple attempts to experimentally
induce systemic infection in cotton were only rarely successful. However,
these attempts, along with field observations, do provide evidence about
possible factors that lead to systemic infection of cotton.
Objective 4. Determine yield effects of TSV on cotton.
This objective was partly achieved. Due to the inconsistent nature of being
able to systemically infect cotton under experimental conditions, effect of
yield could not be assessed under controlled conditions as originally planned.
However, field surveys over multiple seasons do provide evidence to the
likely impact of TSV on yields in cotton.
Objective 5. Dissemination of disease management data based on research objectives.
This objective has been achieved. Several pieces of extension material and
publications have been released to industry and the scientific community.
Methods
3. Detail the methodology and justify the methodology used. Include any discoveries in
methods that may benefit other related research.
Objective 1. Surveys to assess the incidence, distribution and impact of TSV.
Where possible, a standardised disease count method was used in each block inspected by
starting within the margins of the crop, approximately 100 m in from the edge. Plants were
then visually inspected for typical TSV symptoms in approximately 10 m sections (or the
equivalent of 100 plants) back towards the edge of the crop. This was done in a staggered
format where a 10 m section of row was inspected, then moved across 10 rows then inspected
the next 10 m section and repeated until the inspection finished at the edge of the crop. This
approximated a diagonal transect across a number of rows from the interior to the edge of the
block being inspected and resulted in approximately 1000 plants being visually inspected for
symptoms of TSV. This was done to try to avoid any significant edge or single row effects
which may result in disease counts that are not representative of the majority of the block
being inspected. For example, it was common to find much higher incidences of TSV
symptoms in edge rows of a block which were close to the source of infection, parthenium
weed. Plants were also inspected outside of the transect counts (e.g. while moving into the
crop and between rows) to record the presence of TSV. Crops were inspected across several
regions and seasons to assess the distribution of TSV in cotton and to determine whether
seasonal differences in disease incidence occur.
Representative samples with typical TSV symptoms were collected during each survey and
tested for the presence of TSV by enzyme-linked immunosorbent assay (ELISA), essentially
as per the manufacturer’s instructions (AGDIA ELISA reagent set, Cat. No.SRA25500/0500)
to confirm that the visual assessments were accurate. A limited number of ELISA-positive
samples were also tested by TSV-specific PCR to confirm which strain of TSV was present.
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Cotton samples with apparently systemic TSV infection were collected during disease
surveys and different parts of the plants were tested by ELISA to determine the extent of
detectable systemic infection.
During the 2008/09 season, the in-crop distribution of TSV infected plants was determined in
a typical block with apparently scattered TSV infections. A quadrat about 100 m in from the
crop edge (to avoid edge effects) of 21 rows across by 40m long was marked (Fig.1). Every
plant within the quadrat (approximately 8400 plants) was carefully inspected for any local
lesion symptoms of TSV and the position of the plant recorded on a grid map. The same
plants were inspected about 1 month later to see if any further symptoms had developed. This
was done to determine the spatial distribution of TSV infected plants within a crop (i.e. are
they clumped or randomly distributed) and also to track if any plants with local lesion
symptoms developed systemic symptoms.
During the 2010/11 season, the incidence of Cotton bunchy top (CBT) symptoms greatly
increased compared to previous seasons and appeared to be frequently associated with
systemic TSV symptoms which were very rare in the absence CBT in previous seasons.
During that season, disease counts were also done for CBT and TSV symptoms. To
investigate this further, and to confirm the mixed infections of CBT and TSV, a PCR assay
was developed to screen samples for the presence of CBT. This was also done as a pre-
emptive start to the closely related CRDC project (11-12FRP0062) which was due to begin in
July 2011. Partial Cotton bunchy top virus (CBTV) genome sequence (unpublished), isolated
from a CBT sample from Narrabri, NSW was kindly provided by Dr Marc Ellis (CSIRO). In
order to provide the best chance of detecting any possible sequence variations in CBTV
strains, a sequence alignment of different polerovirus species (related to CBTV) was done
and PCR primers were designed to conserved regions of the coat protein gene. The
polerovirus species used for the primer design included Cotton leafroll dwarf virus (CLRDV;
cotton blue disease) isolates from Argentina and Brazil (Genbank accessions GU167940 and
GQ379224), Cucurbit aphid borne yellow virus (CABYV; EU636992) and Chickpea
chlorotic stunt virus (CpCSV; AY956384). The resulting PCR assay was used to screen a
number of cotton samples with CBT symptoms collected as part of this project and was also
utilised by Dr Cherie Gambley as part of project DAQ0001 to confirm visual assessments of
CBT symptoms from samples collected and stored during disease surveys from 2008/9 to
2010/11.
Objective 2. Determine the thrips vector species associated with cotton.
Thrips were collected from 17 cotton crops over the 2008/09 and 2009/10 seasons. No
collections of thrips were made in the 2010/11 season due to very low thrips populations
probably resulting from the very regular, large volume rainfall events experienced during that
season. Thrips were also collected from a number of weeds surrounding crops which were
known to be alternative hosts of TSV. This was done to try to associate the likely thrips
species involved in the movement of TSV from the surrounding alternative hosts into cotton
crops. The collected thrips were initially mounted by the Principal Researcher and species
identifications were confirmed by Department of Employment and Economic Development
(DEEDI) Senior Entomologist, Desley Tree. Tomato thrips (Frankliniella schultzei) is a
known TSV vector species and was commonly associated with cotton and surrounding
weeds. For this reason, F. schultzei was cultured for use in transmission tests described in
Objective 3.
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Objective 3. Examination of factors that lead to systemic infection of cotton.
TSV is transmitted in pollen and requires thrips feeding to facilitate transmission. Under
glasshouse conditions, cotton cv. Sicot 71 (only treated with Dynasty fungicide) of different
ages was exposed to thrips and TSV-infected pollen for different lengths of time (up to
several weeks) to hopefully simulate different levels of disease pressure. Test plants were
observed for typical local lesions of TSV on inoculated leaves, indicating transmission of
TSV, and were also grown for up to several months to determine if systemic symptoms
developed.
TSV-infected pollen was collected from Parthenium hysterophorus (parthenium weed)
known to be infected with the parthenium-TSV strain (see Results of Objective 1 for further
details of TSV strains) and either used fresh in transmission tests or stored at 5ºC for later
use. Frankliniella schultzei (tomato thrips) are an efficient vector species for TSV and were
commonly found on field crops of cotton. They were cultured for use in transmission tests.
Typically, TSV-infected pollen was mixed with tomato thrips and both were sprinkled onto
cotton test plants and also several plants of a known susceptible host such as mung beans or
sunflower to determine the efficiency of the inoculation process. Any plants with suspected
systemic infection were tested by TSV ELISA.
Objective 4. Determine yield effects of TSV on cotton.
This objective was not achieved under controlled conditions due to the significant difficulties
in being able to consistently achieve systemic infection in cotton using controlled inoculation
methods detailed in Objective 3.
The same cultivar of cotton (Sicot 71) was also planted in small plots at two trial sites in the
Clermont region over 3 seasons from 2009 to 2011 in areas known to have a history of high
TSV disease pressure. These trial sites were conducted primarily for screening TSV tolerance
in sunflower cultivars as part of the GRDC project but provided a good opportunity to also
test cotton under high TSV pressure. Infection relied on natural transmission by thrips from
surrounding TSV-infected parthenium. It was hoped that the close proximity of the test
cotton to high density stands of TSV-infected parthenium may simulate a worse case scenario
and provide the most likely conditions for systemic infection to occur and possibly affect
yields.
Conclusions about likely effect of TSV on cotton yields were made based on rarely observed
natural systemic infections in field crops.
Objective 5. Dissemination of disease management data based on research objectives.
Several pieces of extension material, based on the research data obtained, were prepared in
collaboration with other workers (i.e. industry development officers) and also communicated
directly to growers in the TSV affected region of CQ.
Results
4. Detail and discuss the results for each objective including the statistical analysis of
results.
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Objective 1. Surveys to assess the incidence, distribution and impact of TSV.
Over 78,000 plants were visually inspected for typical TSV symptoms across three seasons
(2008/9 to 2010/11) and several regions in central and southern Qld (Table 1). Within the
transect counts, only 107 plants out of the 78,000 were seen with TSV symptoms
(approximately 0.1%) although edge effects were observed when close to parthenium where
up to 10% of plants had local lesion symptoms (Table 3). Cotton planted in the dryland field
trials near Clermont were subjected to relatively high TSV disease pressure and 21% to 26%
of the plants developed typical TSV local lesions in 2009 and 2010 respectively. However,
none of these plants developed systemic symptoms. No TSV-like symptoms were detected in
cotton from regions outside of CQ. The TSV symptoms seen in cotton crops were usually
mild and generally consisted of less than a few diffuse dark purple lesions probably
indicative of inoculation sites where thrips have fed. Systemic TSV symptoms was very
rarely observed in field crops until the 2010/11 season when mixed infections with CBTV
were observed in several locations as discussed further in results for Objective 3.
Cotton samples with and without typical TSV symptoms were collected from disease surveys
across three seasons from 2008/09 to 2010/11 and a total of 458 cotton samples were tested
by ELISA. Of the 125 samples with typical TSV symptoms, 124 were positive by ELISA,
indicating that visual assessment of TSV symptoms is reliable but confirmation of
representative samples is recommended for confirmation, particularly while the disease
inspector becomes familiar with typical TSV symptoms.
TSV infected cotton (usually only local lesion symptoms) was more commonly found in the
2008/9 season than in the 2009/10 season (Table 1) which tended to follow the same level of
infection observed in other susceptible crops such as sunflower and mungbeans from the
same region. However, incidence of TSV infection in cotton appeared to increase in the
2010/11 season (still usually less than 0.5%) even though there appeared to be much lower
TSV disease pressure compared to previous years as indicated by the very low levels of TSV
infection in commercial sunflower crops.
The spatial mapping of TSV-infected plants (Figure 1) shows 87 TSV-infected plants out of
about 8400 plants (1%) and suggests a relatively random distribution of infected plants within
the crop with several small clumps of infected plants. Given the absence of pollen producing
TSV host plants within the crop (the cotton was pre-flowering), TSV is entering the crop
from outside, either as wind blown TSV-infected pollen (and thrips present in the crop are
then facilitating transmission), or thrips carrying TSV-infected pollen are entering the crop,
or a combination of both. The spatial distribution may indicate some thrips entering the crop
are carrying TSV-infected pollen and then moving between neighbouring plants, causing the
small clumps of infected plants. None of the 87 plants with local lesions within the quadrat
area developed systemic symptoms when checked several weeks later and in most cases
plants appeared to be symptomless.
Work by the Principle Researcher conducted in conjunction with a GRDC project
(DAQ00130) has identified two distinct strains of TSV occurring in central Qld (CQ). These
strains differ both genetically and in their respective host ranges and symptoms on some
hosts. One strain appears to be most commonly found in crownbeard, Verbesina encelioides
(Crownbeard-TSV) while the other is most commonly found in parthenium (parthenium-
TSV). A strain-specific multiplex PCR has been developed and used to screen a selection of
cotton TSV isolates from various locations (Table 2). To date, almost all the TSV infections
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found in cotton have been the parthenium-TSV strain. The crownbeard-TSV strain has been
found in cotton near Theodore and Arcturus (Emerald region). Both TSV strains appear to
cause similar symptoms in cotton. Crownbeard occurs outside of central Qld but it is still
unclear if the crownbeard-TSV strain also occurs outside of CQ in other growing regions.
The geographical distribution of TSV disease in cotton (and other susceptible hosts) appears
to be closely related to the distribution of the major alternative host, parthenium weed which
is mostly restricted to the Central Highlands region of CQ.
Severe CBTV disease was observed in the 2010/11 season at several locations with up to
70%, 76% and 96% incidence observed in crops at Jimbour, Mondure and Emerald
respectively. Disease counts at the affected crops at Jimbour and Mondure were done with
Cherie Gambley and these are reported in more detail in the Final Report for DAQ0001. The
severely affected crop to the NE of Emerald was under pivot irrigation and disease counts
were done across the pivot area in May 2011. CBT disease incidence ranged from 96%
(48/50) at 20m from the eastern edge, 48% (24/50) at 200m, 42% (21/50) at 400m, to 15%
(9/61) at about 600m from the eastern edge (close to the western edge). This decreasing
disease incidence from East to West across the pivot area may indicate that infective aphids
were entering the crop from and upwind source as the prevailing winds are NE through to SE.
CBTV infection was confirmed in several samples from Mondure, Jimbour and Emerald by
PCR using the polerovirus primers described in the methods. Preliminary sequencing results
suggest that the CBTV strain found at Mondure and Emerald is genetically distinct from a
CBTV strain from Narrabri previously described (unpublished) by CSIRO workers. It
appears that significant further work may be required to establish the diversity and
geographical distribution of CBTV strains causing CBT and whether these may also display
biological differences such as alternative hosts.
In localised patches along the edge of a CBTV-affected crop in Emerald, up to 70% of
CBTV-affected plants also had apparently systemic TSV infection suggesting there may be
some kind of synergistic relationship between CBTV infection possibly enabling systemic
TSV infection to occur more readily than would normally occur with TSV alone.
In contrast to the extensive damage observed in sunflower and mungbean crops from the
same region, Tobacco streak virus (TSV) has caused negligible damage in commercial cotton
crops surveyed in CQ over the last few seasons. Systemically infected plants are rarely seen
in commercial crops and have also been rarely produced by controlled inoculation tests. It
appears that systemic infection may be transient with mild symptoms being produced
intermittently. With current cultivars and conditions, it appears likely that TSV will continue
to cause only minor levels of mild local lesions with negligible or no impact on yield in the
Emerald irrigation area.
Table 1. Details of TSV survey sites in cotton and results obtained.
Nearest
locality
Lat’ / Longitude
(ddd.ddddd°) of
surveyed block
TSV infected plants /
total plants counted in
disease count
Survey month / year
Emerald -23.46717, 148.09299 < 1 / 1000 Jan 2009
Emerald -23.49057, 148.06358 11 / 1350 Nov 2008
Emerald “ 3 / 800 Dec 2008
Emerald “ 3 / 800 Jan 2009
Emerald -23.44923, 148.11517 8 / 400 Nov 2008
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Emerald “ 0 / 1000 Dec 2008
Emerald “ 1 / 1000 Jan 2009
Emerald -23.48323, 148.32755 15 / 2500 Nov 2008
Emerald “ 1 / 1000 Dec 2008
Emerald -23.48594, 148.07425 3 / 350 Nov 2008
Emerald -23.43470, 148.38672 0 / 1500 Nov 2008
Emerald -23.48706, 148.06866 5 / 2500 Nov 2008
Emerald “ 3 / 1000 Dec 2008
Emerald -23.48024, 148.13860 1 / 800 Nov 2008
Emerald “ 17 / 1800 Dec 2008
Emerald “ 2 / 800 Jan 2009
Emerald -23.47859, 148.12421 1 / 600 Nov 2008
Emerald -23.48485, 148.08302 1 / 500 Nov 2008
Emerald -23.44234, 148.44836 5 / 1500 Nov 2008
Emerald -23.48671, 148.33417 <1 / 1000 Dec 2008
Emerald -23.46604, 148.09209 9 / 2300 Dec 2008
Emerald “ 1 / 2000 Jan 2009
Emerald -23.47436, 148.12743 1/1000 Nov 2009
Emerald -23.48042, 148.13916 0/1000 Nov 2009
Emerald -23.47813, 148.11963 0/1000 Nov 2009
Emerald “ 0/1000 Nov 2009
Emerald -23.45409, 148.11087 0/1000 Nov 2009
Emerald -23.44180, 148.11913 0/1000 Nov 2009
Emerald -23.45647, 148.08199 1/1000 Nov 2009
Emerald -23.46719, 148.09299 0/1000 Nov 2009
Emerald -23.48485, 148.08302 0/1000 Nov 2009
Emerald -23.48706, 148.06866 4/1000 Nov 2009
Emerald -23.50864, 148.09703 0/1000 Nov 2009
Emerald -23.51571, 148.17882 1/1000 Nov 2009
Emerald -23.50626, 148.26410 0/1000 Nov 2009
Emerald -23.48323, 148.32755 0/1000 Nov 2009
Emerald -23.45648, 148.42960 0/900 Nov 2009
Emerald “ 0/1000 Nov 2009
Arcturus -24.00651, 148.49419 1/1000 Nov 2009
Arcturus -24.01223, 148.48190 0/1000 Nov 2009
Comet -23.52426, 148.50995 0/700 Nov 2009
Comet -23.51545, 148.50479 1/1000 Nov 2009
Baralaba -24.31468, 149.82312 0/1000 Nov 2009
Moura -24.65956, 149.95790 0/1000 Nov 2009
Moura “ 0/1000 Nov 2009
Theodore -25.07361, 150.14842 0/1000 Nov 2009
Theodore -25.06951, 150.13605 0/700 Nov 2009
Theodore -24.98759, 150.07486 0/1000 Nov 2009
Theodore -24.96918, 150.07539 0/1000 Nov 2009
Theodore -24.95270, 150.08937 0/1000 Nov 2009
Theodore -24.94148, 150.09113 0/800 Nov 2009
Theodore -24.94263, 149.97980 0/1000 Nov 2009
Theodore -24.93358, 150.00467 1/1000 Nov 2009
Warra -26.87080, 150.91725 0/1000 Dec 2009
Warra -26.87080, 150.91725 0/1000 Dec 2009
Macalister -27.05750, 151.07010 0/1000 Dec 2009
Dalby -27.25818, 151.14732 0/1000 Dec 2009
Dalby -27.24514, 151.14420 0/1000 Dec 2009
Dalby -27.31640, 151.27673 0/1000 Dec 2009
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Cecil Plains -27.58784, 151.26729 0/1000 Dec 2009
Cecil Plains -27.69028, 151.34448 0/500 Dec 2009
Cecil Plains -27.68066, 151.33305 0/1000 Dec 2009
Cecil Plains -27.52365, 151.38870 0/1000 Dec 2009
Emerald -23.47436, 148.12743 0/1000 Dec 2009
Emerald -23.47376, 148.12587 0/200 Dec 2009
Emerald -23.48042, 148.13916 0/500 Dec 2009
Emerald -23.45647, 148.08199 0/200 Dec 2009
Emerald -23.46719, 148.09299 0/900 Dec 2009
Emerald -23.48706, 148.06866 2/1000 Dec 2009
Emerald -23.49057, 148.06358 0/1000 Dec 2009
Arcturus -24.00651, 158.49419 0/500 Dec 2009
Arcturus -24.01550, 148.48021 0/700 Dec 2009
Arcturus -23.99645, 148.50032 0/1000 Dec 2009
Emerald -23.46070, 148.10936 4/1000 Dec 2010
Emerald -23.49057, 148.06358 4/1000 Dec 2010
Emerald -23.48454, 148.06027 8/1000 Dec 2010
Emerald -23.48042, 148.13916 3/1000 Dec 2010
Emerald -23.47376, 148.12587 1/1000 Dec 2010
Emerald -23.47436, 148.12743 3/1000 Dec 2010
Emerald -23.48042, 148.13916 2/1000 Jan 2011
Clermont -22.65219, 147.78154 1/1000 Jan 2011
Clermont -22.65151, 147.78986 0/1000 Jan 2011
Clermont -22.68649, 147.80304 0/500 Jan 2011
Clermont -22.67659, 147.79970 3/1000 Jan 2011
Clermont -22.66915, 147.77313 0/1000 Jan 2011
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Table 2. Identity of TSV strains infecting cotton from various locations.
Isolate number A
Collection
Date
Collection location TSV strain B
TSV-2117
Nov 2007 Foley Rd, Emerald Parthenium-TSV
TSV-2119 Nov 2007 Wills Rd, Emerald Parthenium-TSV
TSV-2120 Nov 2007 Gregory HWY, Emerald Parthenium-TSV
TSV-2144 Jan 2008 Codenwarra Rd, Emerald Parthenium-TSV
TSV-2285 Nov 2008 Maloney’s Rd, Moura Parthenium-TSV
TSV-2399 June 2009 Arcturus, Springsure Crownbeard-TSV
TSV-2509 Nov 2009 Bertles Rd, Emerald Parthenium-TSV
TSV-2510 Nov 2009 Theodore-west Crownbeard-TSV
TSV-2515 Nov 2009 Arcturus, Springsure Parthenium-TSV
TSV-2719 Dec 2010 Wills Rd, Emerald Parthenium-TSV
TSV-2734 Jan 2011 Wills Rd, Emerald Parthenium-TSV
TSV-2735 Jan 2011 Wills Rd, Emerald Parthenium-TSV
TSV-2803 Jan 2011 Donahue Rd, Emerald Parthenium-TSV
TSV-2807 Jan 2011 Donahue Rd, Emerald Parthenium-TSV A
Virus isolate stored in QDEEDI Plant Virus collection. B
TSV strain determined by either sequencing or strain-specific PCR.
Table 3. TSV disease gradient perpendicular to rows at an Emerald site. Row 2 was closest
to TSV infected parthenium which was upwind of crop.
Row # Number of TSV plants
per 250 plants
2 23
4 20
6 16
8 14
10 6
12 0
14 7
16 3
18 1
20 5
22 2
28 0
34 1
40 0
60 1
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Figure 1. Spatial map of TSV-infected cotton plants within a crop. The count area was 21
rows across by 40 m and was centrally located within a cotton block. Black dots represent
plants with typical TSV local lesion symptoms.
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Objective 2. Determine the thrips vector species associated with cotton
Twelve thrips species were identified from the 17 cotton samples (Table 4) and results
indicate that onion thrips (Thrips tabaci) and tomato thrips (Frankliniella schultzei) are two
of the more commonly found species on cotton. Both these species are known vectors of
TSV. Only 1 out of 13 crownbeard and parthenium samples had onion thrips whereas tomato
thrips were on 6 samples of the weeds. This may indicate that tomato thrips could be the most
likely vector species moving TSV-infected pollen from nearby TSV hosts into cotton crops.
Microcephalothrips abdominalis is also a known TSV vector species and was found in 11 of
the 13 nearby crownbeard and parthenium samples but only from 2 of the 17 cotton samples
Table 4. Thrips identified from cotton and nearby weeds.
Collection Date
Host common
name Collector Collection location Thrips species (number of
individuals)
4/11/2008 Cotton M. Sharman Bertles Rd, Emerald Thrips tabaci (11) Caliothrips striatopterus (2) Arorathrips mexicanus (1)
5/11/2008 Cotton M. Sharman Wills Rd, Emerald Frankliniella williamsi (1) Tenothrips frici (1) Desmothrips propinquus (1)
5/11/2008 Cotton M. Sharman Foley Rd, Emerald Thrips tabaci (8) Pseudanaphothrips achaetus (1)
5/11/2008 Cotton M. Sharman Wills Rd, Emerald Thrips tabaci (3) Desmothrips propinquus (1) Caliothrips striatopterus (1)
5/11/2008 Cotton M. Sharman Foley Rd, Emerald Thrips tabaci (1) Frankliniella schultzei (1) Pseudanaphothrips achaetus (1)
5/11/2008 Cotton M. Sharman Bertles Rd, Emerald Thrips tabaci (1) Microcephalothrips abdominalis (1) Tenothrips frici (1) Desmothrips propinquus (1)
11/12/2008 Cotton M. Sharman Bertles Rd, Emerald Thrips tabaci (1) Haplothrips sp (1) Microcephalothrips abdominalis (1) Desmothrips propinquus (1)
8/01/2009 Cotton M. Sharman Wills Rd, Emerald Frankliniella schultzei (11) Bolacothrips sp (1) Caliothrips striatopterus (1)
3/11/2009 Cotton M. Sharman Arcturus Downs, Arcturus Thrips tabaci (4) Tenothrips frici (1) Haplothrips sp (1)
4/11/2009 Cotton M. Sharman Wills Rd, Emerald Thrips tabaci (3)
4/11/2009 Cotton M. Sharman Wills Rd, Emerald Thrips tabaci (1) Anaphothrips sp (1)
1/12/2009 Cotton M. Sharman Dalby Cecil Plains Rd, Dalby
Thrips tabaci (5) Frankliniella schultzei (3) Haplothrips sp (2) Desmothrips tenuicornis (1)
1/12/2009 Cotton M. Sharman Moonie HWY, Dalby Thrips tabaci (6) Frankliniella schultzei (2) Haplothrips (1)
1/12/2009 Cotton M. Sharman Brookstead Norwin Rd, Pittsworth
Thrips tabaci (8) Pseudanaphothrips achaetus (2)
15/12/2009 Cotton M. Sharman Wills Rd, Emerald Thrips tabaci (3)
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Desmothrips tenuicornis (2)
16/12/2009 Cotton M. Sharman Wills Rd, Emerald Thrips tabaci (8) Frankliniella schultzei (1) Desmothrips sp (1)
16/12/2009 Cotton M. Sharman Wills Rd, Emerald Thrips tabaci (12) Frankliniella schultzei (2)
5/11/2008 Crownbeard M. Sharman D. Walker, Wills Rd, Emerald
Microcephalothrips abdominalis (11) Haplothrips sp. (2) Tenothrips frici (1)
6/11/2008 Crownbeard C. Gambley Theodore Pseudanaphothrips achaetus (3) Microcephalothrips abdominalis (2)
8/01/2009 Crownbeard M. Sharman Wills Rd, Emerald Frankliniella schultzei (4) Microcephalothrips abdominalis (2)
27/03/2009 Crownbeard M. Sharman Darling Downs Frankliniella occidentalis (13)
3/06/2009 Crownbeard M. Sharman Arcturas Downs Microcephalothrips abdominalis (36)
6/09/2009 Crownbeard M. Sharman Moree Frankliniella occidentalis (30) Thrips tabaci (11)
16/04/2010 Crownbeard M. Sharman Arcturus Frankliniella schultzei (14) Microcephalothrips abdominalis (1)
7/05/2010 Crownbeard M. Sharman Arcturus Microcephalothrips abdominalis (37)
3/03/2009 Parthenium M. Sharman Kenlogan Rd, Clermont Frankliniella schultzei (24) Microcephalothrips abdominalis (11) Thrips sp. (4)
1/04/2009 Parthenium M. Sharman Kenlogan Rd, Clermont Microcephalothrips abdominalis (21) Frankliniella schultzei (17) Caliothrips striatopterus (2)
2/11/2009 Parthenium M. Sharman Wills Rd, Emerald Microcephalothrips abdominalis (4) Frankliniella schultzei (4) Thrips imaginis (3)
16/12/2009 Parthenium M. Sharman Fernlees, Gindie Microcephalothrips abdominalis (5) Haplothrips froggotti (5)
7/05/2010 Parthenium M. Sharman Fernlees, Gindie Microcephalothrips abdominalis (16) Frankliniella schultzei (4)
Objective 3. Examination of factors that lead to systemic infection of cotton.
At least 33 cotton plants cv. Sicot 71 (only treated with Dynasty fungicide) were inoculated
using tomato thrips (F. schultzei) and TSV pollen from parthenium (parthenium-TSV strain)
under controlled conditions. Plants were of different ages and exposed to TSV inoculum for
varying lengths of time (Table 5). About 80% these test plants displayed local lesions typical
of TSV several days after inoculations started and all susceptible control plants (mungbeans
or sunflowers) developed typical severe systemic symptoms. All plants were grown for
several months post inoculation. Only one cotton test plant did develop systemic symptoms
typical of TSV after 4 months, with necrotic ring spots on the upper-most leaves and was
positive by TSV-specific ELISA and PCR. These systemic symptoms appeared to have been
transient as subsequent growth was symptomless on the same plant. This is not unlike what
has been observed in field infected plants that appear to be displaying systemic symptoms
and subsequent growth is symptomless. This suggests that cotton may have infrequent and
incomplete systemic infection and symptoms can be displayed in a transient manner perhaps
induced by an unknown change in environmental conditions.
In early 2011, TSV disease incidences were very low in commercial sunflower crops and
field trials of sunflower and mung beans conducted as part of GRDC project DAQ00130.
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This was in agreement with very low thrips populations and limited amounts of flowering
parthenium being present in many parts of central Queensland. It was expected that similarly
very low incidences of TSV local lesion symptoms would be observed in cotton crops, and
even fewer systemically infected plants. However, there were several locations in the
Emerald region where many plants appeared to have systemic TSV symptoms in mixed
infections with Cotton bunchy top virus. Several of these mixed infections were confirmed by
TSV ELISA and CBTV PCR. One possible explanation is that when TSV occurs alone in
cotton, the plant defence mechanisms almost completely limit the movement of TSV,
resulting in only local lesions and infrequent, transient systemic symptoms. However,
perhaps CBTV is able to silence the plant defence mechanisms (hence the systemic infections
observed with CBTV) and in doing so, enable TSV to more readily systemically infect the
cotton plants.
TSV was detected in different plant parts from field collected plants that had symptoms
indicating systemic infection. TSV was detected by ELISA in symptomatic parts of the leaf
but not from non-symptomatic parts of the same leaf. TSV was detected in petioles of
symptomatic leaves, in the main stem between leaves that had symptoms (but not in other
parts of the stem), and also in the pollen of plants with apparently systemic symptoms. These
results suggest that infection of cotton by TSV can spread to different parts of the plant but is
perhaps only partially systemic.
Table 5. Details of plant ages and periods of exposure to TSV inoculum in transmission tests
using Sicot 71.
Number of
test plants
Age post
planting at
start (days)
Period of
exposure to
TSV (days)
Number of
inoculation
events
ELISA
results
(number
positive /
total plants)
Systemic
symptoms /
total plants
5 14 23 5 0/5 A
0/5
5 8 23 5 1/5 A, B
1/5
10 15 49 2 n/t C
0/10
4 37 49 2 n/t 0/4
5 14 9 1 0/5 0/5
4 14 18 2 0/5 0/4 A
Tested twice by ELISA at 1 month and 4 months post inoculation. B
One test plant was negative at 1 month, then positive (with typical TSV symptoms) at 4
months. It was also positive by TSV PCR. C
Not tested by ELISA
Objective 4. Determine yield effects of TSV on cotton.
As detailed in results for Objective 3, out of at least 33 test plants in controlled inoculations,
only one developed systemic symptoms of a transient nature that only appeared on a couple
of upper leaves 4 months post inoculation. This made it unfeasible to measure any affect of
systemic infection on yield under controlled conditions.
The incidence of cotton displaying systemic-like symptoms was very low (<0.05%) during
TSV disease surveys in 2008/09 and 2009/10 and often plants that were marked would be
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symptomless in subsequent inspections several weeks later. In 2010/11, the incidence of
systemic-like TSV symptoms was higher but limited to small patches, almost always in
mixed infections with CBT symptoms which were far more severe than the TSV symptoms
alone.
Higher rates of infection were observed in dry-land cotton trial plots grown in the Clermont
region compared to commercial crops in the Emerald irrigation area. This is probably due to
the higher density of the alternative host and higher levels of inoculum (parthenium pollen) in
these dry-land areas. High TSV disease pressure was experienced at one of the two trial sites
in 2009 and 2010 with rates of severe TSV infection in a susceptible sunflower cultivar,
planted at the same site, ranging from 65% to 40% in 2009 and 2010 respectively. Even
though up to 26% of cotton plants in the trial plots displayed TSV local lesions, none
developed systemic symptoms and most plants grew out of the local lesions and became
symptomless.
Systemically infected cotton plants are rarely seen in commercial crops and have also been
rarely produced by controlled inoculation tests. It appears that systemic infection may be
transient with mild symptoms being produced intermittently. With current cultivars and
conditions, it appears likely that TSV will continue to cause only minor levels of mild local
lesions and no likely impact on yield in the Emerald irrigation area.
Objective 5. Dissemination of disease management data based on research objectives.
Several pieces of extension material, based on the research data obtained, were prepared in
collaboration with other workers, including:
A 3 page TSV section in the Integrated Disease Management (IDM) guide for
cotton
Presentation of project outputs at the FUSCOM meeting in 2009 and 2011
Communication of project aims and outcomes with growers from Emerald,
Springsure, Moura, Theodore and the southern Downs during annual surveys.
Update article in Cotton Tales newsletter number 9, 2008/09
Online resource for TSV identification on Cotton CRC website
(http://web.cotton.crc.org.au/content/Industry/Publications/DiseaseMicrobiolo
gy/Tobacco_streak_virus_in_cotton_in_Central_QLD.aspx)
Outcomes
5. Describe how the project’s outputs will contribute to the planned outcomes identified in
the project application. Describe the planned outcomes achieved to date.
The annual surveys for TSV in different regions has provided definitive records for the
presence of TSV in cotton from central Qld and also provided significant surveillance
evidence that TSV is not currently present in cotton growing regions outside of CQ. The
outputs of the project have enabled the industry to recognise the cropping districts in which
TSV is likely to be found and the very unlikely potential for yield losses.
The identification of thrips species from cotton and surrounding TSV weed hosts has
demonstrated that some of the known TSV vector species occur in both the cotton crops and
surrounding weeds and suggest that the tomato thrips (Frankliniella schultzei) may be the
most important vector of TSV into cotton but other species such as Thrips tabaci may also
play a role. Controlled transmission tests demonstrated that F. schultzei is an efficient vector
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of the parthenium-TSV strain, causing high incidences of local lesion symptoms on cotton
test plants. This project (along with outputs from the related GRDC project DAQ00130) have
demonstrated that while TSV has a wide host range, parthenium weed (Parthenium
hysterophorous) appears to always be the major source of the virus in CQ which leads to
TSV disease outbreaks in neighbouring crops. The control of parthenium weed around crops,
particularly upwind of crops, is seen as the most effective way to prevent TSV disease
outbreaks in susceptible crops.
While the initial plans for inducing systemic TSV infection were mostly unsuccessful, these
attempts, along with field observations, clearly demonstrated that systemic infection of TSV
alone in cotton is a very rare event, often with transient symptoms which often disappear with
new growth. This indicates that the factors likely to promote systemic TSV infection rarely
occur in nature. It appears that even though local lesion symptoms can occur at high
incidence with high disease pressure, systemic infection rarely follows and even more rarely
persists in the plant. Any yield loss from the very rare occurrence of systemic TSV infection
is expected to be negligible and almost certainly compensated for in the crop. While the
mixed infections with CBTV did appear to increase the incidence of systemic TSV infection,
the relative impact of TSV in these mixed infections appeared to be negligible compared to
the severe disease symptoms of CBTV. It is unlikely that any control strategies are required
to limit the systemic infection of cotton by TSV. The control of CBTV is a far more
important priority in commercial cotton. However, general farm hygiene to minimise the
presence of the major alternative host, parthenium weed is advised and may be of vital
importance if TSV susceptible rotational crops such as mung beans are grown.
6. Please describe any:-
a) technical advances achieved (eg commercially significant developments, patents
applied for or granted licenses, etc.);
b) other information developed from research (eg discoveries in methodology,
equipment design, etc.); and
c) required changes to the Intellectual Property register.
The CTAB extraction method developed and used for isolating virus genomic material for
use in PCR diagnostics may be useful for other viral pathogens of cotton and will probably be
used in the CRDC project (11-12FRP00062) to investigate alternative hosts of CBTV. The
polerovirus PCR primers developed will be further refined and also used in the project 11-
12FRP00062.
Conclusion
7. Provide an assessment of the likely impact of the results and conclusions of the research
project for the cotton industry. What are the take home messages?
In contrast to the extensive damage observed in sunflower and mungbean crops from the
same region, Tobacco streak virus (TSV) has caused no measurable damage in commercial
cotton crops surveyed in Central Qld over the seasons 2008/9 to 2010/11. No TSV infected
cotton was found in regions outside of Central Qld and the geographical distribution of TSV
disease in cotton (and other susceptible hosts) appears to be closely related to the distribution
of the major alternative host, parthenium weed. Systemically infected plants are rarely seen in
commercial crops and have also been rarely produced by controlled inoculation tests. It
appears that systemic infection may be transient with only mild symptoms being produced
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intermittently. With current cultivars and conditions, it appears likely that TSV will continue
to cause only minor levels of mild local lesions with no impact on yield. It appears that no
specific control strategies are required to limit the impact of TSV in cotton. As demonstrated
by recent outbreaks, the control of CBTV is of far greater importance for the cotton industry.
However, general farm hygiene to minimise the presence of the major alternative host of
TSV, parthenium weed, is advised and may be of vital importance if TSV susceptible
rotational crops such as mung beans are grown.
Extension Opportunities
8. Detail a plan for the activities or other steps that may be taken:
(a) to further develop or to exploit the project technology.
> The extraction methods and PCR primers for detection of CBTV (and other
poleroviruses) developed in this project will be used and further developed in CRDC
project 11-12FRP00062 to investigate various aspects of the epidemiology and
genetic diversity of CBTV.
(b) for the future presentation and dissemination of the project outcomes.
> Continued contact with cotton growers and industry members through CRDC
project 11-12FRP00062 will enable further dissemination of project outcomes.
(c) for future research.
> Further studies (not currently anticipated) may be useful to test the hypothesis that
systemic TSV infection in cotton is greatly enhanced in plants already infected with
CBTV. If this is true it may be possible to determine the mechanism by which this
occurs which could be a form of gene silencing induced by CBTV which then enables
TSV to more readily move through the cotton plant.
> Preliminary results suggest that there is more than one strain of CBTV causing CBT
disease in cotton. Many things are unknown, such as: the complete genome diversity
of each of the strains (and possibly others), the likelihood of genetic recombination
between strains, the impact that genetic variation between strains may have on the
effectiveness of any future CBTV-resistant cotton lines that may be developed, the
geographic distribution of these CBTV strains, the relative incidence and importance
of these strains and any biological differences such as host range. Some of these
unknowns will be investigated as part of the new project 11-12FRP00062 (such as
host range) but other aspects are outside the objectives of this project and resource
and time limitations would mean that further investment would be required to
investigate these aspects adequately.
8. A. List the publications arising from the research project and/or a publication plan.
(NB: Where possible, please provide a copy of any publication/s)
Sharman M, Thomas JE, Persley DM (2008) First report of Tobacco streak virus in
sunflower (Helianthus annuus), cotton (Gossypium hirsutum), chickpea (Cicer arietinum)
and mung bean (Vigna radiata) in Australia. Australasian Plant Disease Notes 3, 27-29.
Sharman M, Persley DM, Thomas JE (2009) Distribution in Australia and seed transmission
of Tobacco streak virus in Parthenium hysterophorus. Plant Disease 93, 708-712.
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Planned journal publications in conjunction with the outputs of GRDC project DAQ00130
include: a paper describing the genetic diversity and detection of TSV strains in Australia,
and a paper describing further aspects of the epidemiology, thrips and seed transmission, and
natural host range of TSV strains found in Australia.
B. Have you developed any online resources and what is the website address?
Online resource for TSV identification on Cotton CRC website
(http://web.cotton.crc.org.au/content/Industry/Publications/DiseaseMicrobiolo
gy/Tobacco_streak_virus_in_cotton_in_Central_QLD.aspx)
I contributed content for the Crop Consultants Australia online survey to
determine importance of Cotton bunchy top:
http://cropconsultants.com.au/cbt
Part 4 – Final Report Executive Summary
Provide a one page Summary of your research that is not commercial in confidence, and that
can be published on the World Wide Web. Explain the main outcomes of the research and
provide contact details for more information. It is important that the Executive Summary
highlights concisely the key outputs from the project and, when they are adopted, what this
will mean to the cotton industry.
In 2006, Tobacco streak virus (TSV) was identified as the causal agent of the devastating
sunflower necrosis disease in central Queensland (CQ), and subsequently in 2007 as the
cause of major losses in mungbeans in the same area. It has been a major factor in the recent
downturn in the sunflower industry in CQ. Surveys in 2007/2008 as part of a one year
scoping study (project 03DAQ005) found TSV in cotton in CQ. The symptoms were mostly
confined to the feeding sites of the thrips and appeared as reddish spots and rings, but only
occasionally the plants were systemically infected and showed a chlorotic mosaic and leaf
deformation.
The major objectives of this project (DAQ0002) were to determine: the incidence and
distribution of TSV in cotton and its likely effect on yield; the thrips vector species associated
with TSV infections in cotton; and the factors that may lead to systemic infections.
In contrast to the extensive damage observed in sunflower and mungbean crops from the
same region, TSV has caused no measurable damage in commercial cotton crops surveyed in
CQ over the seasons 2008/9 to 2010/11. No TSV infected cotton was found in regions
outside of CQ and the geographical distribution of TSV disease in cotton (and other
susceptible hosts) appears to be closely related to the distribution of the major alternative
host, parthenium weed. The most likely thrips species responsible for transmission of TSV
into cotton is the tomato thrips (Frankliniella schultzei) and onion thrips (Thrips tabaci).
Systemically infected plants are rarely seen in commercial crops and have also been rarely
produced in controlled tests. It appears that systemic infection may be transient with only
mild symptoms being produced intermittently. With current cultivars and conditions, it
2
.
A
n
n
u
a
l
R
e
p
o
r
t
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appears likely that TSV will continue to cause only minor levels of mild local lesions with no
impact on yield in cotton crops.
It appears that no specific control strategies are required to limit the impact of TSV in cotton.
However, general farm hygiene to minimise the presence of the major alternative host of
TSV, parthenium weed, is advised and may be of vital importance if TSV susceptible
rotational crops such as mung beans are grown.
For further information, contact:
Murray Sharman Plant Pathologist (Virology) Department of Employment, Economic Development and Innovation
Address: Department of Employment, Economic Development and Innovation Level 2C-West Ecosciences Precinct GPO Box 267 Brisbane Queensland, 4001 Australia
Telephone: + 61 7 3255 4339 Facsimile: + 61 7 3846 2387 Mobile: 0467 721 400 Email: [email protected]